KULIAH II MEKANIKA TEKNIK TI KESEIMBANGAN PARTIKEL (2D)

1. KULIAH IIMEKANIKA TEKNIK TIKESEIMBANGAN PARTIKEL (2D) OLEH: ALIEF WIKARTA, ST JURUSAN TEKNIK MESIN, FTI – ITS SURABAYA, 2007

2. Equilibrium of a Particle (2-D) Today’s Objectives: Students will be able to : a) Draw a free body diagram (FBD), and, b) Apply equations of equilibrium to solve a 2-D problem. For a given cable strength, what is the maximum weight that can be lifted ?

3. Free Body Diagram (FBD) (2-D)

4. Equations of Equilibrium (2-D) Since particle A is in equilibrium, the net force at A is zero. So FAB + FAD +FAC = 0 or  F = 0 In general, for a particle in equilibrium,  F = 0or Fxi + Fy j = 0 = 0 i +0 j (A vector equation) • Or, written in a scalar form, • These are two scalar equations of equilibrium (EofE). They can be used to solve for up to two unknowns. • Fx= 0and  Fy= 0

5. EXAMPLE Note : Engine mass = 250 Kg FBD at A Write the scalar EofE: +   Fx = TB cos 30º – TD = 0 +  Fy = TB sin 30º – 2.452 kN = 0 Solving the second equation gives: TB = 4.90 kN From the first equation, we get: TD = 4.25 kN

6. F = 600 N θ= 25o Problem Solving (2-D) Given: The car is towed at constant speed by the 600 N force and the angle  is 25°. Find: The forces in the ropes AB and AC. Plan: 1. Draw a FBD for point A. 2. Apply the EofE to solve for the forces in ropes AB and AC.

7. 600 N F = 600 N FBD at point A A 30° 25° θ= 25o FAC FAB Problem Solving (2-D) Applying the scalar EofE at A, we get; +  Fx = FAC cos 30° – FAB cos 25° = 0 +  Fy = -FAC sin 30° – FAB sin 25° + 600 = 0 Solving the above equations, we get; FAB = 634 N FAC = 664 N

8. Example • SOLUTION: • Construct a free-body diagram for the particle at the junction of the rope and cable. • Determine the unknown force magnitudes. In a ship-unloading operation, a 15.6 kN automobile is supported by a cable. A rope is tied to the cable and pulled to center the automobile over its intended position. What is the tension in the rope?

9. EXAMPLE Given: Sack A weighs 20 N. and geometry is as shown. Find: Forces in the cables and weight of sack B. Plan: 1. Draw a FBD for Point E. 2. Apply EofE at Point E to solve for the unknowns (TEG & TEC). 3. Repeat this process at C.

10. EXAMPLE (continued) A FBD at E should look like the one to the left. Note the assumed directions for the two cable tensions. The scalar EofE are: +   Fx = TEGsin 30º – TEC cos 45º = 0 +   Fy = TEGcos 30º – TEC sin 45º – 20 N = 0 Solving these two simultaneous equations for the two unknowns yields: TEC = 38.6 N TEG = 54.6 N

11. EXAMPLE(continued) Now move on to ring C. A FBD for C should look like the one to the left. The scalar EofE are:    Fx = 38.64 cos 45 – (4/5) TCD = 0    Fy = (3/5) TCD + 38.64 sin 45 – WB = 0 Solving the first equation and then the second yields TCD = 34.2 N and WB = 47.8 N .

12. READING QUIZ 1) When a particle is in equilibrium, the sum of forces acting on it equals ___ . (Choose the most appropriate answer) A) a constant B) a positive number C) zero D) a negative number E) an integer. 2) For a frictionless pulley and cable, tensions in the cable (T1 and T2) are related as _____ . A) T1 > T2 B) T1 = T2 C) T1 < T2 D) T1 = T2 sin 

13. ATTENTION QUIZ 3. Using this FBD of Point C, the sum of forces in the x-direction ( FX)is ___ . Use a sign convention of +  . A) F2 sin 50° – 20 = 0 B) F2 cos 50° – 20 = 0 C) F2 sin 50° – F1 = 0 D) F2 cos 50° + 20 = 0 F2 20 N 50° C F1

14. SOAL TANTANGAN Jika b = 4 m, tentukan harga P dan jarak a

15. TERIMA KASIH